Difference between revisions of "Fasciolosis"

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PARASITES TREMATODES

Fasciolosis

Fasciola hepatica - Joaquim Castellà Veterinary Parasitology Universitat Autònoma de Barcelona

Fasciola hepatica - Wikimedia Commons

Fasciola hepatica adults from a horse - Castellà Veterinary Parasitology Universitat Autònoma de Barcelona

The adult liver fluke, Fasciola hepatica, lives in the bile ducts of a wide range of animals, including sheep, cattle, rabbits and, less often, horses. It can infect humans causing a painful abdominal disease. The intermediate host in the UK is a mud snail, Lymnaea truncatula. It causes significant economic losses in western parts of the British Isles due to deaths, clinical and subclinical cattle disease confined mostly to the younger stock. Fasciolosis is a seasonal disease with more serious outbreaks occurring in some years than in others. A similar but slightly larger species, F. gigantica, occurs in wetter tropical regions.

Ovine Fasciolosis

Acute fasciolosis

Sudden death
Normally September-November
Enlarged pale, friable, haemorrhagic liver
More than 1000 immature flukes in liver parenchyma

NOTE: Acute disease is rarely seen in cattle

Sub-acute fasciolosis

Rapid weight-loss over 1-2 weeks
Occurs October-December
Normochromic anaemia
Enlarged liver with large haemorrhages
More than 500 flukes - 50:50 immature and adult

Chronic fasciolosis

Progressive weight-loss over weeks or months
Occurs January-March
Normochromic anaemia often becoming hypochromic
Hypoalbuminaemia leading to oedema
Small, distorted cirrhotic liver
Enlarged bile ducts
More than 250 adult flukes

NOTE: Calcification of bile duct in cattle → 'pipe-stem' liver

Sub-clinical effects

In sheep, fleece weight and fibre quality are affected even by small fluke burdens. There is some evidence that reproductive performance (number of lambs born and growth-rate of lambs) is inversely influenced, but this has not been well documented.
Liver condemnations cause economic losses at slaughter
Longer finishing times to slaughter weight and reduced carcass value in beef cattle
Reduced milk yield and quality in dairy cows

Migration and pathology

Migration

Metacercariae excyst → immature flukes present in the small intestine → migrate across the peritoneal cavity (about 1 week) → to the liver → migrate through the liver parenchyma for 6-7 weeks becoming more destructive as they grow → enter bile ducts

The prepatent period is 10-12 weeks

Pathogenesis of acute fasciolosis

Liver pathology
- Flukes develop from 0.1mm-1cm within the liver parenchyma causing trauma, necrotic tracts, and haemorrhages
- Glutamate dehydrogenase (GDH) is released by damaged cells
Acute damage to liver causes post-necrotic scarring → shrinkage of affected tissues and hypertrophy of normal tissue → the typical appearance of the liver in chronic disease
Chronic damage to bile ducts → peribiliary fibrosis

(Note: other complex events also occur, including disruption of haemodynamics, monolobular fibrosis, egg-granulomas etc.)

Black disease (Infectious Necrotic Hepatitis)
- caused by a toxin produced by Clostridium novyi type B.
- It is commonly associated with liver fluke infestation because migrating flukes → liver necrosis → anaerobic conditions → clostridial multiplication → toxin production → disease

Pathogenesis of chronic fasciolosis

Bile duct damage
- Adult flukes (2-5cm long) in bile ducts feed on epithelium and blood
- Chronic inflammatory responses → fibrosis of bile duct wall (and, in cattle, calcification)
- Gamma glutamyl transpeptidase released by damaged cells
- Ulceration and haemorrhage of bile duct → epithelial hyperplasia and increased mucosal permeability
Anaemia
- 250 flukes → up to 50ml of blood loss daily → 10 times increase in rate of erythropoiesis → normochronic anaemia until iron stores are exhausted → hypochromic anaemia.
Hypoalbuminaemia
- Albumin (and other plasma proteins) lost into bile duct because of

Whole blood loss
Increased epithelial permeability

- → Increased catabolic rate by 2.5x → increased nitrogen loss via urine
- The effects seen depend on the magnitude of nitrogen loss

There is no obvious effect (although animal is still in abnormal physiological state)
Reduced weight-gain and/or wool growth and/or milk production
Loss of body tissue (i.e. weight-loss); hypoalbuminaemia → reduced plasma oncotic pressure → oedema

Disease manifestations

Large numbers of metacercariae ingested over a short period of time leads to acute disease
Smaller numbers ingested over a longer period of time leads to chronic disease
Feed intake
- Fluke infections cause reduced food intake

NOTE: chronic fasciolosis occurs at a time of year when animals are on a low plane of nutrition. This combined with the reduced food 
intake causes a significant effect on the development and severity of clinical and subclinical fasciolosis.

Species susceptibility
- The proportion of flukes that reach the bile ducts is determined mainly by
  - The fibroplastic potential of the liver
  - The effectiveness of the protective immune responses (which are ineffective in sheep)
- Therefore, establishment rate is

sheep>cattle>pig

Snail biology

Lymnaea truncatula - Wikimedia Commons

Lymnaea truncatula

5-10mm long
Brown-black shell with 5-6 spirals
1st spiral is greater than half the total length
The shell opens on the right (when held with the opening upwards)
Feeds on green slime
Multiplies rapidly when food is abundant
Most die during the British winter (unless very mild)
Survivors lay eggs in spring, which hatch in June

Habitats

Lymnaea are found in muddy areas (but not on highly acidic soils)
Habitats may be permanent (dry summer) or temporary (wet summer)

Epidemiology

In temperate areas, there are two superimposed epidemiological cycles, known as the summer and winter infections of the snail. On mainland Britain, the summer cycle predominates as a high proportion of snails perish during the winter, but very occasionally, weather sequences allow the winter cycle to affect the pattern of disease. On the west coast of Ireland, the winter cycle of events determines the timing of clinical outbreaks.

Summer infection of the snail

Fluke eggs passed in spring

→ hatch in June (i.e. coincident with snail hatch)

→ miracidia infect newly hatched snails

→ develop and multiply in snail hepatopancreas during summer

→ cercariae shed from late August onwards

→ metacercariae ingested by sheep

→ immature flukes migrate through liver

→ acute disease September-November; or chronic diesease January onwards

Winter infection of the snail

Fluke eggs passed in late summer:

→ infect snails

→ development halted when temperature <10°C (i.e. flukes trapped in hibernating snails through the winter)

→ development resumes when temperature >10°C

→ cercariae shed from July

→ disease from August

Geographical distribution of disease

Transmission is dependent on the snail, and therefore associated with snail habitats. These are more plentiful in high rainfall areas such as found on the western side of the British Isles, or alongside drainage canals in low-lying areas such as the Romney Marsh (or the Netherlands). It is important to remember that sheep and cattle are often bred in Ireland or western Britain and transported to the east of the country for fattening. Infected animals may therefore be found in areas where no transmission occurs.

Weather patterns and disease risk

Wet summer Many fluke and snail eggs hatching and snail habitats expanded, therefore:

→ snail population increases rapidly

→ many infected snails

→ many cercariae shed

→ high density of metacercariae on herbage

→ increased risk of disease

Dry summer Few fluke and snail eggs hatching and snails restricted to permanent habitats, therefore:

→ snail populations small and overcrowded

→ few infected snails, high mortality

→ few cercariae shed

→ few metacercariae confined to restricted areas

→ reduced risk of disease

Forecasting Fasciolosis

Several prediction models have been developed. They evaluate the wetness of the soil from May to October by taking account of rainfall patterns and evapo-transpiration. Seasonal weighting factors are applied. June is a particularly influential month.

A drought in late summer can reverse a potentially dangerous trend, and so unqualified forecasts should not be issued prematurely.

A high snail density will only lead to disease if infection is present (i.e. if fluke eggs have been deposited onto the habitat by farm or wild animals). Local biological interpretation of computer generated predictions is therefore required.

These forecasting models can provide valuable information for the farming community. MAFF (before DEFRA) used to provide an annual forecast, but this is now discontinued.

Diagnosis